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RENEWABLE ENERGY SYSTEMS WIND ENERGY (2) Prof. Ibrahim El-mohr Prof. Ahmed Anas Lec. 6 Outline 2 Wind Turbine Components Wind Turbine Aerodynamics Maximum Power Point Tracking (MPPT) Wind Energy System Configurations Wind Turbine Components 3 Turbine Blade 4 The blade is the most distinctive and visible component of a wind turbine. It is also responsible for carrying out one of the most essential tasks of the energy conversion process: transforming the wind kinetic energy into rotational mechanical energy. Blades have greatly evolved in aerodynamic design and materials from the early windmill blades made of wood and cloth. Modern blades are commonly made of aluminum, fiberglass, or carbon-fiber composites that provide the necessary strength-to-weight ratio, fatigue life, and stiffness while minimizing the weight. Turbine Blade 5 Although single- and two-bladed wind turbines have found practical applications, the three-blade rotor is considered the industry standard for large wind turbines. Turbines with fewer blades operate at higher rotational speeds. This is an advantage from the drive train point of view since they require a gearbox with a lower gear ratio, which translates into lower cost. In addition, fewer blades imply lower costs. However, acoustic noise increases proportionally to the blade tip speed. Therefore, acoustic noise is considerably higher for singleand two-bladed turbines, which is considered an important problem, particularly in populated areas. Turbine Blade 6 Singe-blade turbines have an asymmetrical mechanical load distribution. The turbine rotors are aerodynamically unbalanced, which can cause mechanical vibrations. Moreover, higher rotational speed imposes more mechanical stress on the blade, turbine structure, and other components, such as bearings and gearbox, leading to more design challenges and lower life span. Rotors with more than three blades are not common since they are more expensive (more blades). Operating at lower rotational speeds requires a higher gear ratio. The lagging wind turbulence of one blade can affect the other blades since they are closer to each other. Hence, the three-blade rotor presents the best trade-off between mechanical stress, acoustic noise, cost, and rotational speed for large wind turbines. Turbine Blade 7 The aerodynamic operating principle of the turbine blade is similar to the wings of an airplane. It can be explained by Bernoulli's principle. Turbine Blade 8 The curved shape of the blade creates a difference between the wind speed above (vw1) and below (vw2) the blade, as illustrated in the pervious figure. The airflow above the blade is faster than the one below (vw1 > vw2), which, according to the Bernoulli's principle, has the inverse effect on the pressure (pw2 >pw\). The pressure difference between the top and bottom of the blade results in a net lift force Fw on the blade. The force applied at a certain distance of a pivot (the turbine shaft) produces torque, which creates the rotational movement of the wind turbine. Turbine Blade 9 One of the important parameters for controlling the lift force of the blade is the angle of attack , which is defined as the angle between the direction of the wind speed vw and the cord line of the blade as shown in the figure. For a given blade, its lift force Fw can be adjusted by a. When this angle is equal to zero, no lift force or torque will be produced, which often occurs when the wind turbine is stopped (parked) for maintenance or repair. The power of an air mass flowing at speed vw through an area/i can be calculated by Turbine Blade 10 The wind power captured by the blade and converted into mechanical power can be calculated by where Cp is the power coefficient of the blade. This coefficient has a theoretical maximum value of 0.59 according to the Betz limit. With today's technology, the power coefficient of a modern turbine usually ranges from 0.2 to 0.5, which is a function of rotational speed and number of blades. For a three-blade turbine with a rotor diameter of 82 m and power coefficient of Cp = 0.36, the captured power is 2 MW at a wind speed of 12 m/s and air density of p = 1.225 kg/m3. Turbine Blade 11 As can be observed from the pervious equation, there are three possibilities for increasing the power captured by a wind turbine: the wind speed vw, the power coefficient Cp, and the sweep area A. Since wind speed cannot be controlled, the only way to increase wind speed is to locate the turbines in regions with higher average wind speeds. An example is the offshore wind farm, where the wind speed is usually higher and steadier than that on land. The captured power is a cubic function of the wind speed. Doubling the average wind speed would increase the wind power by eight times. Turbine Blade 12 Second, the wind turbine can be designed with larger sweep area (i.e., longer blades) to capture more power. An increase in the blade length has a quadratic effect on the sweep area and the captured power. This explains the trend of increasing the rotor diameter experienced during the last decade. Finally, the third way of increasing the captured power is by improving the power coefficient of the blade through a better aerodynamic design. Additional blade requirements, such as lightning protection, audible noise reduction, transportation, optimum shape and weight, as well as manufacturability, make the blade design a challenging task. Pitch Mechanism 13 Pitch Mechanism 14 The pitch mechanism in large wind turbines enables the rotation of the blades on their longitudinal axis. It can change the angle of attack of the blades with respect to the wind, by which the aerodynamic characteristics of the blade can be adjusted. This provides a degree of control over the captured power to improve conversion efficiency or to protect the turbine. When the wind speed is at or below its rated value, the angle of attack of the blades is kept at an optimal value, at which the turbine can capture the maximum power available from the wind. Pitch Mechanism 15 When the wind speed exceeds the rated value, the pitch mechanism is activated to regulate and limit the output power, thus keeping the power output within the designed capability. For this purpose, a pitch range of around 20 to 25 degrees is usually sufficient. When the wind speed increases further and reaches the limit of the turbine, the blades are completely pitched out of the wind (fully pitched or feathering), and no power will be captured by the blades. The wind turbine is then shut down and protected. Pitch Mechanism 16 The pitch mechanism can be either hydraulic or electric. Electric pitch actuators are more common nowadays since they are simpler and require less maintenance. Traditionally, all blades on the rotor hub are pitched simultaneously by one pitch mechanism. Modern wind turbines are often designed to pitch each blade individually, allowing an independent control of the blades and offering more flexibility. The pitch system is usually placed in the rotor hub together with a backup energy storage system for safety purposes (an accumulator for the hydraulic type or a battery for the electric type). Gearbox 17 The rotor of a large three-blade wind turbine usually operates in a speed range from 6-20 rpm. This is much slower than a standard 4- or 6-pole wind generator with a rated speed of 1500 or 1000 rpm for a 50 Hz stator frequency and 1800 or 1200 rpm for a 60 Hz stator frequency. Therefore, a gearbox is necessary to adapt the low speed of the turbine rotor to the high speed of the generator. The gearbox conversion ratio (rgb), also known as the gear ratio, is designed to match the high-speed generator with the low-speed turbine blades. For a given rated speed of the generator and turbine, the gearbox ratio can be determined by Gear ratio versus the rated turbine speed (for s = 0.01) 18 Gearbox 19 The wind turbine gearboxes normally have multiple stages to achieve the high conversion ratio needed to couple the turbine rotor and generator. For example, with a rated turbine rotor speed of 15 rpm and a 4-pole, 50 Hz induction generator, a gear ratio of 100 is needed, as shown in the next figure which is difficult to achieve by one gear stage. The gearbox usually generates a high level of audible noise. The noise mainly arises from the meshing of individual teeth. The efficiency of the gearbox normally varies between 95% and 98%. The gearbox is a major contributor to the cost of the wind turbine in terms of initial investment and maintenance. Two Stage Gearbox of a large wind turbine 20 Rotor Mechanical Brake 21 Rotor Mechanical Brake 22 A mechanical brake is normally placed on the high-speed shaft between the gearbox and the generator, but there are some turbines in which the brake is mounted on the low-speed shaft between the turbine and gearbox. The main advantage of placing the brake on the high-speed shaft is that it handles much lower braking torque. The brake is normally used to aid the aerodynamic power control (stall or pitch) to stop the turbine during high speed winds or to lock the turbine into a parking mode during maintenance. Rotor Mechanical Brake 23 Hydraulic and electromechanical disc brakes are often used. To minimize the wear and tear on the brake and reduce the stress on drive train during the braking process, most large wind turbines use the aerodynamic power control to reduce the turbine speed to a certain level or zero, and then the mechanical brake to stop or lock the wind turbine. However, the mechanical brake should be able to bring the turbine rotor to a complete stop at any wind speeds, as required by some standards such as IEC61400-1. Wind Turbine Generator 24 The conversion of rotational mechanical energy to electric energy is performed by the generator. Different generator types have been used in wind energy systems over the years. These include the squirrel cage induction generator (SCIG), doubly fed induction generator (DFIG), and synchronous generator (SG) (wound rotor and permanent magnet) with power ratings from a few kilowatts to several megawatts. The SCIG is simple and rugged in construction. It is relatively inexpensive and requires minimum maintenance. Wind Turbine Generator 25 Traditional direct grid-connected wind energy systems are still available in today's market. All these turbines use SCIGs and operate at a fixed speed. Two-speed SCIGs are also commercially available, in which a tapped stator winding can be adapted to change the pole pairs to allow two-speed operation. The SCIGs are also employed in variable-speed wind energy systems. To date, the largest SCIG wind energy systems are around 3.5 MW in offshore wind farms. The DFIG is the current workhorse of the wind energy industry. The stator of the generator is connected to the grid directly, while the rotor is interfaced with the grid through a power converter system with reduced power capacity. Wind Turbine Generator 26 The DFIG typically operates about 30% above and below synchronous speed, sufficient for most wind speed conditions. It also enables generator-side active power control and gridside reactive power control. The reduced-capacity converter is less expensive and requires less space, which makes the DFIG WECS popular in today's market. The synchronous generator is very well suited for direct-drive wind turbines. Wind Turbine Generator 27 Wound rotor synchronous generators (WRSGs) and permanent magnet synchronous generators (PMSGs) are used in wind energy systems with a maximum power rating up to 7.5 MW. Permanent magnet generators have higher efficiency and power density as compared to wound rotor generators. Recent trends indicate a move toward direct drive turbines with PMSG. Although most SG-based turbines are direct driven, some manufacturers have developed SG turbines with gearbox drive trains. Yaw Drive 28 The main function of the yaw drive is to maximize the captured wind energy by keeping the turbine facing into the wind. It usually consists of more than one electric motor drive, yaw gear, gear rim, and bearing. Yaw Drive 29 The yaw drive uses a planetary gear to lower the rotating speed of the yaw gear. All the motors are commanded by the same signals and lock after turning the wind turbine into the desired position. The yaw system typically needs to generate torque from 10,000 to 70,000 Nm to turn the nacelle. In older wind turbines, the yaw control is also used for power regulation. For example, to limit the power captured by the turbine during high wind gusts, the turbine can be horizontally turned out of the wind. However, this technology is no longer in use since the power regulation by means of yaw control is very limited for three reasons. Yaw Drive 30 First, the large moment of inertia of the nacelle and turbine rotor along the yaw axis reduces the speed of response of the yaw system. Second, the cosine relationship between the component of the wind speed perpendicular to the rotor disc and the yaw angle makes the power capture insensitive to the yaw angle. For example, 15 degrees of yaw change only brings power reduction of a few percent. Third, yaw control imposes mechanical stress on different parts of the turbine, causing vibrations that could reduce the life span of the turbine. Tower and Foundation 31 The main function of the tower is to support the nacelle and the turbine rotor, and provide the rotor with the necessary elevation to reach better wind conditions. Most towers for wind turbines are made of steel. Concrete towers or towers with a concrete base and steel upper sections are sometimes used as well. The height of the tower increases with the turbine power rating and rotor diameter. In addition, the tower must be at least 25 to 30 m high to avoid turbulence caused by trees and buildings. Small wind turbines have towers as high as a few blade rotor diameters. However, the towers of medium and large turbines are approximately equal to the turbine rotor diameter. Tower and Foundation 32 The tower also houses the power cables connecting the generator or power converters to the transformer located at the base of the tower. In some cases, the transformer is also included in the nacelle and the cables connect the transformer to the wind farm substation. In large multi-megawatt turbines, the power converters may be located at the base of tower to reduce the weight and size of the nacelle. The stairs to the nacelle for maintenance are often attached along the inner wall of the tower in large wind turbines. The wind-turbine foundation is also a major component in a wind energy system. Tower and Foundation 33 The types of foundations commonly used for on-land wind turbines include slab, multipile, and monopile types. Foundations for offshore wind turbines are particularly challenging since they are located at variable water depths and in different soil types. They have to withstand harsh conditions as well. This explains the wide variety of foundations developed over the years for offshore turbines, some more proven than others. Foundations for offshore wind turbines 34 Wind Sensors (Anemometers) 35 The pitch/stall and yaw control systems require wind speed and direction measurements, respectively. The pitch/stall control needs the wind speed to determine the angle of attack of the blade for optimal operation. The yaw control requires the wind direction to face the turbine into the wind for maximum wind power capture. In addition, in variable speed turbines, the wind speed is needed to determine the generator speed for maximum power extraction. Most large wind turbines are equipped with sensors, also referred to as anemometers, for wind data collection and processing. The wind speed sensor is usually made of a three-cup vertical-axis micro-turbine driving an optoelectronic rotational speed transducer. Wind Sensors (Anemometers) 36 Ultrasonic anemometers are also used in practical wind turbines. They measure the wind speed by emitting and receiving acoustic signals through the air and monitoring the transmission time. Several emitters and receptors are disposed in such a way that a three-dimensional measurement can be made. The transmission time is affected by both wind speed and direction. With a given physical distribution of the sensors, the wind speed and direction can be computed from the propagation times. The ultrasonic anemometers are more accurate and reliable than the mechanical ones with moving parts. However, they are more expensive. Wind Turbine Aerodynamics 37 The aerodynamic design of the turbine blade has a significant influence on the amount of energy captured from the wind. The design should consider the means to limit the power and rotating speed of the turbine rotor for wind speeds above the rated value in order to keep the forces on the mechanical components (blade, gearbox, shaft, etc.) and the output power of the generator within the safety margins. This becomes critical for larger turbines as they would have narrower safety margins due to cost and size constraints. Power Characteristic of a Wind Turbine 38 The power characteristics of a wind turbine are defined by the power curve, which relates the mechanical power of the turbine to the wind speed. The power curve is a wind turbine's certificate of performance that is guaranteed by the manufacturer. The International Energy Association (IEA) has developed recommendations for the definition of the power curve. The recommendations have been continuously improved and adopted by the International Electrotechnical Commission (IEC). The standard, IEC61400-12, is generally accepted as a basis for defining and measuring the power curve. Wind Turbine Power Curve 39 A typical power curve is characterized by three wind speeds: cut-in wind speed, rated wind speed, and cut-out wind speed, where PM is the mechanical power generated by the turbine and vw is the wind speed. The cut-in wind speed, as the name suggests, is the wind speed at which the turbine starts to operate and deliver power. The blade should be able to capture enough power to compensate for the turbine power losses. The rated wind speed is the speed at which the system produces nominal power, which is also the rated output power of the generator. The cut-out wind speed is the highest wind speed at which the turbine is allowed to operate before it is shut down. For wind speeds above the cut-out speed, the turbine must be stopped, preventing damage from excessive wind. Turbine Mechanical Power versus Wind Speed Curve 40 Wind Turbine Power Curve 41 The wind turbine starts to capture power at the cut in wind speed. The power captured by the blades is a cubic function of wind speed until the wind speed reaches its rated value. To deliver captured power to the grid at different wind speeds, the wind generator should be properly controlled with variable speed operation. As the wind speed increases beyond the rated speed, aerodynamic power control of blades is required to keep the power at the rated value. This task is performed by three main techniques: passive stall, active stall, and pitch control. Aerodynamic Power Control: Passive Stall, Active Stall, and Pitch Control 42 The aerodynamics of wind turbines are very similar to that of airplanes. The blade rotates in the wind because the air flowing along the surface that is not facing the wind moves faster than that on the surface against the wind. This creates a lift force to pull the blade to rotate. The angle of attack of the blade plays a critical role in determining the amount of force and torque generated by the turbine. Therefore, it is an effective means to control the amount of captured power. There are three aerodynamic methods to control the capture of power for large wind turbines: passive stall, active stall, and pitch control. Passive-Stall Control 43 In passive-stall-controlled wind turbines, the blade is fixed onto the rotor hub at an optimal (rated) angle of attack. When the wind speed is below or at the rated value, the turbine blades with the rated angle of attack can capture the maximum possible power from the wind. With the wind speed exceeding the rated value, the strong wind can cause turbulence on the surface of the blade not facing the wind. As a result, the lifting force will be reduced and eventually disappear with the increase of the wind speed, slowing down the turbine rotational speed. This phenomenon is called stall. The stall phenomenon is undesirable for airplanes, but it provides an effective means to limit the power capture to prevent turbine damage. Passive-Stall Control 44 The operating principle of the passive-stall control is illustrated in the next figure, where the lift force produced by higher than rated wind, which is the stall lifting force Fw-stall, is lower than the rated force Fw-rated. Passive-Stall Control 45 The blade profile is aerodynamically designed to ensure that stall occurs only when the wind speed exceeds the rated value. To ensure that the blade stall occurs gradually rather than abruptly, the blades for large wind turbines are usually twisted along the longitudinal axis by a couple of degrees. The passive-stall-controlled wind turbines do not need complex pitch mechanisms, but the blades require a complex aerodynamic design. The passive stall may not be able to keep the captured power PM at a constant value. It may exceed the rated power at some wind speeds, which is not a desirable feature. Passive-Stall Control 46 Active-Stall Control 47 In active-stall turbines, the stall phenomenon can be induced not only by higher wind speeds, but also by increasing the angle of attack of the blade. Thus, active-stall wind turbines have adjustable blades with a pitch control mechanism. When the wind speed exceeds the rated value, the blades are controlled to turn more into the wind, leading to the reduction of captured power. The captured power can, therefore, be maintained at the rated value by adjusting the blade angle of attack. A qualitative example of the active-stall principle is illustrated in the next figure. 48 When the blade is turned completely into the wind, as shown in the dashed blade, the blade loses all interaction with the wind and causes the rotor to stop. This operating condition can be used above the cutout wind speed to stop the turbine and protect it from damage. Active-Stall Control 49 With active-stall control, it is possible to maintain the rated power above the rated wind speed, as can be appreciated in the next figure. Active-stall controlled large megawatt wind turbines are commercially available. Pitch Control 50 Similar to the active-stall control, pitch-controlled wind turbines have adjustable blades on the rotor hub. When the wind speed exceeds the rated value, the pitch controller will reduce the angle of attack, turning the blades (pitching) gradually out of the wind. The pressure difference in front and on the back of the blade is reduced, leading to a reduction in the lifting force on the blade. The operating principle of the pitch control is illustrated in the next figure. When the wind is below or at the rated speed, the blade angle of attack is kept at its rated (optimal) value R. With higher than the rated wind, the angle of attack of the blade is reduced, causing a reduction in lift force, Fw-pitch. Pitch Control 51 When the blade is fully pitched, the blade angle of attack is aligned with the wind, as shown by the dashed blade in the figure, and no lift force will be produced. The turbine will stop rotating and then be locked by the mechanical brake for protection. Active-Stall Control versus Pitch Control 52 Both pitch and active-stall controls are based on rotating actions on the blade, but the pitch control turns the blade out of the wind, leading to a reduction in lift force, whereas the active-stall control turns the blades into the wind, causing turbulences that reduce the lift force. MAXIMUM POWER POINT TRACKING (MPPT) CONTROL 53 The control of a variable-speed wind turbine below the rated wind speed is achieved by controlling the generator. The main goal is to maximize the wind power capture at different wind speeds, which can achieved by adjusting the turbine speed in such a way that the optimal tip speed ratio T, opt is maintained. For a given wind speed, each power curve has a maximum power point (MPP) at which the optimal tip speed ratio T, opt is achieved. To obtain the maximum available power from the wind at different wind speeds, the turbine speed must be adjusted to ensure its operation at all the MPPs. MAXIMUM POWER POINT TRACKING (MPPT) CONTROL 54 MAXIMUM POWER POINT TRACKING (MPPT) CONTROL 55 The trajectory of MPPs represents a power curve, which can be described by MAXIMUM POWER POINT TRACKING (MPPT) CONTROL 56 According to wind turbine power curve, the operation of the wind turbine can be divided into three modes: parking mode, generator-control mode, and pitch-control mode: Parking mode. When the wind speed is below cut-in speed, the turbine system generates less power than its internal consumption and, therefore, the turbine is kept in parking mode. The blades are completely pitched out of the wind, and the mechanical brake is on. Generator-control mode. When the wind speed is between the cut-in and rated speed, the blades are pitched into the wind with its optimal angle of attack. The turbine operates with variable rotational speeds in order to track the MPP at different wind speeds. This is achieved by the proper control of the generator. MAXIMUM POWER POINT TRACKING (MPPT) CONTROL 57 Pitch-control mode. For higher than rated wind speeds but below the cut-out limit, the captured power is kept constant by the pitch mechanism to protect the turbine from damage while the system generates and delivers the rated power to the grid. The blades are pitched out of the wind gradually with the wind speed, and the generator speed is controlled accordingly. When the wind speed reaches or exceeds the cut-out speed, the blades are pitched completely out of the wind. No power is captured, and turbine speed is reduced to zero. The turbine will be locked into the parking mode to prevent damage from the strong wind. MPPT with Turbine Power Profile 58 MPPT with Optimal Tip Speed Ratio 59 MPPT with Optimal Torque Control 60 Wind Energy System Configurations 61 Fixed-Speed WECS without Power Converter Interface 62 FIXED-SPEED WECS The fixed-speed wind energy systems can be divided into Single-speed WECS, in which the generator operates at only one fixed speed; and Two-speed WECS, in which the generator can operate at two fixed speeds. (1) Single-Speed WECS 63 A typical configuration for a high-power (MWs), fixed-speed wind energy system is shown in the figure. The turbine is normally of horizontal-axis type with three rotor blades rotating at low speeds, for example, 15 rpm as the rated speed. Single-Speed WECS 64 Squirrel cage induction generators are exclusively used in the system. Assuming that a four pole generator is connected to a 50 Hz grid, its speed is slightly higher than 1500 rpm, for which a gear ratio of about 100:1 is required. To assist the start-up of the turbine, a soft starter is used to limit the inrush current in the generator winding. The soft starter is essentially a three-phase AC voltage controller. It is composed of three pairs of bidirectional thyristor switches. To start the system, the firing angle of the thyristors is gradually adjusted such that the voltage applied to the generator is increased gradually from zero to the grid voltage level. As a result, the stator current is effectively limited. Once the startup process is over, the soft starter is bypassed by a switch, and the WECS is then connected to the grid through a transformer. Single-Speed WECS 65 To compensate for the inductive reactive power consumed by the induction generator, a capacitor-based power-factor (PF) compensator is normally used. In practice, the compensator is composed of multiple capacitor banks, which can be switched into or out of the system individually to provide an optimal compensation according to the operating conditions of the generator. Due to the use of a cost-effective and robust squirrel-cage induction generator with inexpensive soft starter, the fixedspeed WECS features simple structure, low cost, and reliable operation. However, compared to the variable-speed WECS, the fixed-speed system has a lower energy conversion efficiency since it can achieve the maximum efficiency only at one given wind speed. (2) Two-Speed WECS 66 Two-Speed Operation by Changing Number of Poles; To improve the energy conversion efficiency, two-speed SCIG wind energy systems have been developed. The speed of the generator changes with the number of stator poles. Switching from a fourpole to a six- or eight-pole configuration can introduce a speed reduction of one-third or one-half, respectively. The number of poles can be changed by reconfiguring the stator winding through appropriate parallel and series connection of the stator coils. With the number of poles switched from four to six, for example, a generator connected to a 50 Hz grid can operate at slightly higher than 1500 rpm and 1200 rpm, so the system can capture the maximum power at two different wind speeds, leading to improvements in energy efficiency. Two-Speed WECS 67 Two-Speed Operation by Two Generators; The two-speed operation can also be obtained by having two separate generators mechanically coupled to a single shaft: one is a fully rated high-speed generator (normally four poles) and the other is a partially rated low-speed generator (six or eight poles). The selection of the generators is done through switch S according to the wind speeds. At high wind speeds, switch S is in Position 1, connecting the high-speed generator to the grid. When the wind speed reduces to a certain level, S is switched to Position 2. The low-speed generator is selected and delivers power to the grid. Two-Speed WECS 68 This WECS configuration uses two off-the-shelf generators and, therefore, does not need a customized generator to achieve the two-speed operation. However, this approach requires two separate generators and also a long drive train that needs special consideration for the coupling of both generators. Two-Speed WECS 69 The two-speed operation can also be obtained by using a split gearbox with two shafts. The two shafts have the same gear ratio, and each shaft is connected to a separate SCIG. Similar to the single-shaft configuration, a fully rated four-pole generator is selected at high wind speeds, whereas a partially rated six- or eight-pole generator is switched on at low wind speeds. This configuration requires a special gearbox, but offthe-shelf generators may be used. The single- and dual-shaft WECS configurations require two generators, which increases the cost and weight of the system in addition to the added complexity in the mechanical components. Therefore, they have found limited practical applications. VARIABLE-SPEED INDUCTION GENERATOR WECS 70 Wound-Rotor Induction Generator with External Rotor Resistances. Doubly Fed Induction Generator WECS with Reduced- Capacity Power Converters. SCIG Wind Energy Systems with FullCapacity Power Converters. (3) Wound-Rotor Induction Generator (WRIG) with External Rotor Resistances 71 The system configuration is the same as that of the fixedspeed wind energy system except that the SCIG is replaced with the WRIG. The external rotor resistance, is made adjustable by a converter composed of a diode bridge and an IGBT chopper. The equivalent value of Rex, seen by the rotor varies with the duty cycle of the chopper. Wound-Rotor Induction Generator (WRIG) with External Rotor Resistances 72 The torque-slip characteristics of the generator vary with the external rotor resistance Rext. With different values of R ext, the generator can operate at different operating points. This introduces a moderate speed range, usually less than 10% of the rated speed. Wound-Rotor Induction Generator (WRIG) with External Rotor Resistances 73 Slip rings and brushes of the WRIG can be avoided in some practical WECS by mounting the external rotor resistance circuit on the rotor shaft. This reduces maintenance needs, but introduces additional heat dissipation inside the generator. The main advantage of this configuration compared to the variable-speed WECS is the low cost and simplicity. The major drawbacks include limited speed range, inability to control grid-side reactive power, and reduced efficiency due to the resistive losses (4) Doubly Fed Induction Generator WECS with Reduced- Capacity Power Converter 74 The variable-speed DFIG wind energy system is one of the main WECS configurations in today's wind power industry. Doubly Fed Induction Generator WECS with Reduced- Capacity Power Converter 75 The stator is connected to the grid directly, whereas the rotor is connected to the grid via reduced-capacity power converters. A two-level IGBT voltage source converter (VSC) system in a back-to-back configuration is normally used. Since both stator and rotor can feed energy to the grid, the generator is known as a doubly fed generator. The typical stator voltage for the commercial DFIG is 690 V and power rating is from a few hundred kilowatts to several megawatts Doubly Fed Induction Generator WECS with Reduced- Capacity Power Converter 76 The rotor-side converter (RSC) controls the torque or active/reactive power of the generator while the grid-side converter (GSC) controls the DC-link voltage and its AC-side reactive power. Since the system has the capability to control the reactive power, external reactive power compensation is not needed. The speed range of the DFIG wind energy system is around ±30%, which is 30% above and 30% below synchronous speed. The speed range of 60% can normally meet all the wind conditions and, therefore, it is sufficient for the variablespeed operation of the wind turbine. The maximum slip determines the maximum power to be processed by the rotor circuit, which is around 30% of the rated power. Doubly Fed Induction Generator WECS with Reduced- Capacity Power Converter 77 Therefore, the power flow in the rotor circuit is bidirectional: it can flow from the grid to the rotor or vice versa. This requires a four-quadrant converter system. However, the converter system needs to process only around 30% of the rated power. The use of reduced-capacity converters results in reduction in cost, weight, and physical size as well. Compared with the fixed-speed systems, the energy conversion efficiency of the DFIG wind turbine is greatly enhanced. Power converters normally generate switching harmonics. To solve the problems caused by the harmonics, different types of harmonic filters are used in practical wind energy conversion systems Doubly Fed Induction Generator WECS with Reduced- Capacity Power Converter 78 The L filter is often used in the generator-side converters to reduce the harmonic distortion of the generator current and voltage, which leads to a reduction of harmonic losses in generator's magnetic core and winding. LC filters may also be used to achieve better results. Doubly Fed Induction Generator WECS with Reduced- Capacity Power Converter 79 The LCL filter is often employed in the grid-side converters to meet stringent harmonic requirements specified by various grid codes. LC filters are also found in practical WECS, but they are not as effective as the LCL filters. An added benefit of using these filters is that they can effectively mitigate high dv/dt problems caused by fast switching of semiconductor switches. However, both LC and LCL filters may cause LC resonances. The filter parameters and resonant modes should be carefully designed to avoid possible LC oscillations. The filter shown in fig. e is essentially a three-phase capacitor for current source converters. In addition to the filter function, the capacitor is required by the CSC to assist in the commutation of the semiconductor switches. Therefore, this filter capacitor is indispensable in current source converters. (5) SCIG Wind Energy Systems with Full-Capacity Power Converters 80 With Two-Level Voltage Source Converters. The two converters are identical in topology and linked by a DClink capacitive filter. The generator and converters are typically rated for 690 V, and each converter can handle up to 0.75 MW. SCIG Wind Energy Systems with Full-Capacity Power Converters 81 For wind turbines larger than 0.75 MW, the power rating of the converter can be increased by paralleling IGBT modules. Measures should be taken to ensure minimum circulating current among the parallel modules. To minimize the circulating current, issues such as dynamic and static characteristics of IGBTs, design and arrangement of gate driver circuits, and physical layout of IGBT modules and DC bus should be considered. Some semiconductor manufacturers provide IGBT modules for parallel operation to achieve a power rating of several megawatts. SCIG Wind Energy Systems with Full-Capacity Power Converters 82 An alternative approach to the paralleled converter channels is illustrated in the figure, where three converter channels are in parallel for a megawatt IG wind turbine. Each converter channel is mainly composed of two-level voltage source converters in a back-to-back configuration with harmonic filters. An additional benefit of the paralleled converter channels is the improvement of energy efficiency. SCIG Wind Energy Systems with Full-Capacity Power Converters 83 For example, when the system delivers a small amount of power to the grid at low wind speeds, one or two converter channels out of three can be turned off, leading to higher system efficiency. This configuration provides redundancy as well, due to the paralleled converter channels. If one channel fails, the other two channels can continue to operate under certain conditions. However, similar to the paralleled IGBT modules, measures should be taken to minimize circulating current among the paralleled converter channels. SCIG Wind Energy Systems with Full-Capacity Power Converters 84 With Three-Level NPC Converters. The low-voltage converters discussed before are cost-effective at low power levels. As the power rating of wind turbines increases to several megawatts, medium-voltage (MV) wind energy systems of 3 kV or 4 kV become competitive. SCIG Wind Energy Systems with Full-Capacity Power Converters 85 For example, the rated current of the generator and inverter in a 4 kV/3 MW wind turbine is around 433 A, which is much lower than 2510 A for a 690 V system. The cable cost and losses are reduced in the MV wind energy systems. The pervious figure shows a MV wind turbine that employs a full-capacity converter system with a MV generator. Two back-to-back connected three-level neutral point clamp (NPC) converters are used in the system, where the converter power rating can reach 6 MVA without any series or parallel switching devices or converters. High-voltage switching devices, such as HV-IGBT and IGCTs of 4.5 kV to 6.5 kV, can be employed in the converters. SCIG Wind Energy Systems with Full-Capacity Power Converters 86 To minimize switching losses, the device switching frequency is normally around a few hundred hertz. Although the NPC converter has found application in commercial mediumvoltage SG WECS, commercial medium-voltage SCIG wind turbines have not been reported yet. All the power converters presented in previous configurations have been of the voltage source type. The current source converter (CSC) technology is also suitable for use in multi megawatt wind energy systems. The CSC technology has been successfully used in highpower applications such as large industrial drives [8], but the application of this technology to MV wind energy systems is yet to be explored. SCIG Wind Energy Systems with Full-Capacity Power Converters 87 Figure 5-11 shows a typical current source converter configuration for variable speed wind energy systems. Two identical converters are employed, one operating as a PWM current source rectifier (CSR) on the generator side and the other as a PWM current source inverter (CSI) on the grid side. As discussed in Chapter 4, these converters require a threephase capacitor on their respective AC sides to assist commutation of switching devices and mitigate switching harmonics. The rectifier and inverter are linked by a DC choke Ldc, which smoothes the DC current and also decouples the generator from the grid. SCIG Wind Energy Systems with Full-Capacity Power Converters 88 The current source converter features simple converter structure with low switch count, low switching dvldt, and reliable short-circuit protection compared to the voltagesource converter. Although the dynamic response of the CSC may not be as fast as the VSC, it is a promising converter configuration for use in medium-voltage wind energy systems. VARIABLE-SPEED SYNCHRONOUS GENERATOR WECS 89 Synchronous generator wind energy systems have many more configurations than the induction generator WECS. This is mainly due to the fact that (1) the synchronous generator provides the rotor flux by itself through permanent magnets or rotor field winding and, thus, diode rectifiers can be used as generator-side converters, which is impossible in the induction generator WECS, and (2) it is easier and more cost-effective for the synchronous generator to have multiple-pole (e.g., 72 poles) and multiple-phase (e.g., six phases) configurations than its counterpart. (6) Configuration with Full-Capacity Backto-Back Power Converters 90 With Two-Level VSC and Three-Level NPC Converters. (6) Configuration with Full-Capacity Backto-Back Power Converters 91 The configuration of SG wind energy systems with fullcapacity power converters utilizes back-to-back two-level voltage source converters are employed in low-voltage wind energy systems and three-level NPC converters are used in medium voltage wind turbines. Similar to the SCIG system presented earlier, parallel modules or converter channels are required in the LV systems for generators of more than 0.75 MW, whereas in the MV systems a single NPC converter can handle power up to a few megawatts. Not all the SG wind turbines need a gearbox. When a lowspeed generator with high number of poles is employed, the gearbox can be eliminated. The gearless wind turbine is attractive due to the reduction in cost, weight, and maintenance. (6) Configuration with Full-Capacity Backto-Back Power Converters 92 With PWM Current Source Converters. The current source converter has a number of advantages over its counterpart. It is a promising converter topology for large SG WECS at the medium-voltage level of 3 kV or 4 kV. the medium-voltage level of 3 kV or 4 kV. (7) Configuration with Diode Rectifier and DC/DC Converters 93 With Diode Rectifier and Multichannel Boost Converters. (7) Configuration with Diode Rectifier and DC/DC Converters 94 To reduce the cost of the wind energy systems, the two-level voltage source rectifier can be replaced by a diode rectifier and a boost converter. This converter configuration cannot be used for SCIG wind turbines since the diode rectifier cannot provide the magnetizing current needed for the induction generator. The diode rectifier converts variable generator voltage to a DC voltage, which is boosted to a higher DC voltage by the boost converter. It is important that the generator voltage at low wind speeds be boosted to a sufficiently high level for the inverters, which ensures the delivery of the maximum captured power to the grid in the full wind speed range. (7) Configuration with Diode Rectifier and DC/DC Converters 95 The two-level inverter controls the DC link voltage and gridside reactive power. The power rating of the system is in the range of a few kilowatts to several hundred kilowatts, and can be further increased to the megawatt level by using a twochannel or three-channel interleaved boost converter as shown in figure b. Compared with the PWM voltage source rectifier, the diode rectifier and boost converter are simpler and more costeffective. However, the stator current waveform is distorted due to the use of the diode rectifier, which increases the losses in the generator and causes torque ripple as well. Both system configurations illustrated in the figure are used in practical systems. (7) Configuration with Diode Rectifier and DC/DC Converters 96 An alternative WECS configuration using a six-phase generator with a multichannel boost converter is shown in the next figure, where the output of the generator is rectified by two diode bridge rectifiers. To increase the power rating, a three-channel interleaved boost converter and two paralleled three-phase inverters are used. This topology provides a lowcost alternative as compared to the full-capacity back-to-back VSC solution. (7) Configuration with Diode Rectifier and DC/DC Converters 97 With Diode Rectifier and Multilevel Boost Converters. The three-level boost converter is composed of two single- boost converters connected in cascade. This alternative has found practical application with a power rating up to 1.2 MW. (7) Configuration with Diode Rectifier and DC/DC Converters 98 With Diode Rectifier and Buck Converter for CSC WECS Considering the concept of duality for voltage- and current source converters, a CSC configuration with diode rectifier and buck converter can be deduced from the VSC configurations presented before. (7) Configuration with Diode Rectifier and DC/DC Converters 99 The boost converter in the VSC topology that boosts the DC output voltage can be replaced by a buck converter that boosts the DC output current. This enables the use of the simple diode rectifier for the CSC configurations. The buck converter is the natural choice for this topology as it needs an output inductor, which can also serve as the DC-link inductor needed by the CSC. This is contrast to the VSC topology, where the boost converter shares the DC capacitor with the inverter. (7) Configuration with Diode Rectifier and DC/DC Converters 100 By controlling the duty cycle of the buck converter and modulation index and delay angle of the inverter, the generator-side active power (or generator torque), DC link current, and grid-side reactive power can be tightly controlled. Compared to the back-to-back CSC configuration the buck converter based WECS represents a reliable, simple, and costeffective solution. However, the stator current contains higher THD due to the use of the diode rectifier, causing harmonic losses and torque ripples (8) Configurations with Distributed Converters for Multi-winding Generators 101 In addition to paralleling devices or converters as discussed previously, it is possible to increase the power rating of wind energy systems by using distributed converters for a generator with multiple windings or for multiple generators. Correspondingly, the grid-side transformer can also be designed with multiple windings. This configuration has a number of advantages, including Low-power converters for megawatt wind turbines. The total generated power can be delivered to the grid through a number of standard two-level voltage source converters. These converters can be mass-produced with low cost and improved reliability. (8) Configurations with Distributed Converters for Multi-winding Generators 102 No circulating current or power de-rating. The distributed converters are insulated from each other. There are no circulating currents among the converters, which also leads to no power de-rating for the converters. Low torque ripple and harmonic distortion. In six-phase synchronous generators, the stator voltages across the two stator windings are phase-shifted such that low-order harmonic currents produced by the generator-side converters can be cancelled, leading to the reduction in torque ripples. On the grid side, phase shifting transformers can be used, which can cancel low-order harmonic currents produced by the grid-side converters. Consequently, smaller size filters can be used with reduced costs and losses. (9) Configuration with Multi-winding Generators. 103 The multi-winding generator approach is illustrated in the figure, where a six-phase generator is used and the power is delivered to the grid through two distributed converter channels. (9) Configuration with Multi-winding Generators. 104 Each converter channel is composed of two-level voltage source converters and filters. Since the two sets of the stator windings are insulated, there is no circulating current between the two converter channels. Therefore, the outputs of the two converter channels can be connected to the same transformer winding. Alternatively, a phase-shifting transformer can be used, as shown in dashed lines of Figure 5-19. With a proper design of switching schemes of the two inverters, the grid-side harmonic performance of the system can be further improved by the phase-shifting transformer. (9) Configuration with Multi-winding Generators. 105 Another example for the multi-winding generator is shown, where the generator has six sets of three-phase windings, and each winding feeds the wind power to the grid through a power converter channel. The system configuration is the same as that with the six-phase generator except that there are no phase displacements between the stator voltages of different windings. (10) Configuration with Multiple Generators 106 A recent configuration with four synchronous generators and distributed power converter stages is shown. The system uses a distributed gearbox with multiple high-speed shafts that drive four independent generators. (10) Configuration with Multiple Generators 107 Each generator is interfaced to the grid via a partially rated converter channel, composed of a diode bridge rectifier and two-level voltage source converters. Since the power is divided among the four distributed converters, the wind turbine can reach multi-megawatt power range without using paralleled switching devices or converters. The main advantage of this configuration is the high power density achieved by the distributed gearbox and multiple generator system. (10) Configuration with Multiple Generators 108 This leads to a light and small nacelle for a multi-megawatt WECS and thus reduces transportation and installation costs. The use of diode rectifier and standard two-level converter makes this a cost-effective solution. This configuration can provide redundancy for possible fault tolerant operation. If one converter channel has a fault, it can be taken out of service, and the power can be easily distributed among the other channels. If the wind speed is high, the blades can be pitched to reduce captured power to compensate for the faulty converter channel. The main disadvantage of the system is that it requires a complex gearbox. This system is commercially available on the market. Summary of WECS configurations 109 110 111